Habitable Zones & Global Climate

Climate Bistability At The Inner Edge Of The Habitable Zone Due To Runaway Greenhouse And Cloud Feedbacks

By Keith Cowing
Status Report
astro-ph.EP
August 23, 2024
Filed under , , , , , , , ,
Climate Bistability At The Inner Edge Of The Habitable Zone Due To Runaway Greenhouse And Cloud Feedbacks
Schematic representation of the two-column model. Gray boxes represent the free atmosphere (pressure < 1 bar). Blue boxes represent the shortwave extinction layer (presure ∼ 1 bar). Orange arrows represent shortwave radiative fluxes, blue arrows represent outgoing longwave radiation to space, and black arrows represent atmospheric heat advection. The dayside column consists of a cloudy part and a clear-sky part; we also include an optional stratospheric (< 0.1 bar) nightside cloud that blocks nightside longwave emission. The updated modules compared to Yang & Abbot (2014) are indicated by ovals. -- astro-ph.EP

Understanding the climate dynamics at the inner edge of the habitable zone (HZ) is crucial for predicting the habitability of rocky exoplanets. Previous studies using Global Climate Models (GCMs) have indicated that planets receiving high stellar flux can exhibit climate bifurcations, leading to bistability between a cold (temperate) and a hot (runaway) climate.

However, the mechanism causing this bistability has not been fully explained, in part due to the difficulty associated with inferring mechanisms from small numbers of expensive numerical simulations in GCMs.

In this study, we employ a two-column (dayside and nightside), two-layer climate model to investigate the physical mechanisms driving this bistability. Through mechanism-denial experiments, we demonstrate that the runaway greenhouse effect, coupled with a cloud feedback on either the dayside or nightside, leads to climate bistability.

We also map out the parameters that control the location of the bifurcations and size of the bistability. This work identifies which mechanisms and GCM parameters control the stellar flux at which rocky planets are likely to retain a hot, thick atmosphere if they experience a hot start.

This is critical for the prioritization of targets and interpretation of observations by the James Webb Space Telescope (JWST). Furthermore, our modeling framework can be extended to planets with different condensable species and cloud types.

Bowen Fan, Da Yang, Dorian S. Abbot

Comments: 4 figures, submitted to ApJL
Subjects: Earth and Planetary Astrophysics (astro-ph.EP); Atmospheric and Oceanic Physics (physics.ao-ph)
Cite as: arXiv:2408.12563 [astro-ph.EP] (or arXiv:2408.12563v1 [astro-ph.EP] for this version)
https://doi.org/10.48550/arXiv.2408.12563
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Submission history
From: Bowen Fan
[v1] Thu, 22 Aug 2024 17:25:59 UTC (508 KB)
https://arxiv.org/abs/2408.12563
Astrobiology

Explorers Club Fellow, ex-NASA Space Station Payload manager/space biologist, Away Teams, Journalist, Lapsed climber, Synaesthete, Na’Vi-Jedi-Freman-Buddhist-mix, ASL, Devon Island and Everest Base Camp veteran, (he/him) 🖖🏻